High levels of population differentiation for mitochondrial DNA haplotypes inPinus radiata,muricata, andattenuata

We analyzed mitochondrial (mt) DNA restriction fragment length polymorphisms (RFLPs) associated with cytochrome oxidase, subunit I (coxI)-related gene sequences in 268 trees derived from 19 natural populations of three species of pines from California (USA): Monterey pine (Pinus radiata D. Don), bishop pine (P. Muricata D. Don), and knobcone pine (P. attenuata Lemm.). Total genomic DNA was digested with four restriction endonucleases and probed with a 750-bp fragment of the mitochondrialcoxI gene amplified fromP. attenuata via the polymerase chain reaction (PCR). ThecoxI gene is repeated at least 4 times in some populations, and all variants that we observed resulted from complex rearrangements rather than from point mutations. There was limited intrapopulation variation, but strong differentiation among populations. When applied to haplotype frequencies, Nei's gene diversity within populations (H_s) averaged 7% (±3), and G_st varied from 75% forP. Radiata to 96% forP. muricata. The high degree of population differentiation for mtDNA suggests that it can be a powerful marker of population differences, but its rapid rate of structural evolution appears to result from recombination among a limited number of repetitive elements-giving frequent homoplasious fragment phenotypes. The phylogenetic trees disagreed with results from chloroplast DNA, nuclear gene, and morphological studies.     

Analysis of mitochondrial DNA variation in the population of Oroks

Mitochondrial DNA (mtDNA) variation was studied in population of Oroks (N = 61), the indigenous inhabitants of Eastern Siberia. Most of the mtDNA types examined fell into five haplogroups (C, D, G, M10, and Y) typical of Eastern Eurasian populations. For three haplogroups (D, C, and M10), the founder effect was established. In one individual, a unique lineage belonging to haplogroup HV and typical of Caucasoids was detected.Translated from Genetika, Vol. 41, No. 1, 2005, pp. 78–84.Original Russian Text Copyright © 2005 by Bermisheva, Kutuev, Spitsyn, Villems, Batyrova, Korshunova, Khusnutdinova.     

Analysis of mitochondrial DNA variation in the population of Oroks

Mitochondrial DNA (mtDNA) variation was studied in population of Oroks (n = 61), the indigenous inhabitants of Eastern Siberia. Most of the mtDNA types examined fell into five haplogroups (C, D, G, M10, and Y) typical of Eastern Eurasian populations. For three haplogroups (D, C, and M10), the founder effect was established. In one individual, a unique lineage belonging to haplogroup HV and typical of Caucasoids was detected.     

Complete mitochondrial genome sequencing reveals novel haplotypes in a Polynesian population

The high risk of metabolic disease traits in Polynesians may be partly explained by elevated prevalence of genetic variants involved in energy metabolism. The genetics of Polynesian populations has been shaped by island hoping migration events which have possibly favoured thrifty genes. The aim of this study was to sequence the mitochondrial genome in a group of Maoris in an effort to characterise genome variation in this Polynesian population for use in future disease association studies. We sequenced the complete mitochondrial genomes of 20 non-admixed Maori subjects using Affymetrix technology. DNA diversity analyses showed the Maori group exhibited reduced mitochondrial genome diversity compared to other worldwide populations, which is consistent with historical bottleneck and founder effects. Global phylogenetic analysis positioned these Maori subjects specifically within mitochondrial haplogroup--B4a1a1. Interestingly, we identified several novel variants that collectively form new and unique Maori motifs--B4a1a1c, B4a1a1a3 and B4a1a1a5. Compared to ancestral populations we observed an increased frequency of non-synonymous coding variants of several mitochondrial genes in the Maori group, which may be a result of positive selection and/or genetic drift effects. In conclusion, this study reports the first complete mitochondrial genome sequence data for a Maori population. Overall, these new data reveal novel mitochondrial genome signatures in this Polynesian population and enhance the phylogenetic picture of maternal ancestry in Oceania. The increased frequency of several mitochondrial coding variants makes them good candidates for future studies aimed at assessment of metabolic disease risk in Polynesian populations.     

Spread of mitochondrial DNA haplotypes in population of scots pine (Pinus sylvestris L.) in northern European Russia

The variability of the first intron of the nad7 gene of Scots pine mitochondrial DNA was investigated in 15 populations in northeast of European Russia and in three populations in Belarus, Sweden, and the Voronezh region. Restriction Fragments Length Polymorphism of the PCR product (PCR-RFLP) and sequencing were used. The investigated samples were compared with the populations studied previously [1, 2]. The haplotype, which is absolutely dominant in the eastern part of the Scots pine range [1, 2], was fixed in the Kirov, Arkhangelsk, and Kostroma regions; Komi; and Chuvashia. The extreme northeastern discovery of an alternative haplotype that is present in most European populations and occurs the most frequently in eastern Scandinavia was made in the Vologda region. These results support the hypothesis that the population of Scots pine in northeast Russia and Fennoscandia originated from different glacial refugia.     

Genetic peculiarity of the yakut population from the autosomal loci data

The autosomal gene pool of Yakuts was analyzed with a panel of polymorphic Alu insertions. The observed allele frequencies were typical for other Asian ethnic groups. Genetic differentiation of three Yakut populations was relatively high, 2%. East Siberian ethnic groups were shown to have a common gene pool and to experience no intense gene flow from other populations. Development of the Yakut gene pool was assumed to involve no substantial genetic effect of neighboring populations. The results fit both autochthonous and southern origin hypotheses.     

Genetic and demographic structure of the yakut population: reproduction indices

Genetic and demographic information for the Yakut population living in the Republic of Sakha (Yakutia) is presented. The mean number of children per woman constituted 4.605. Crow's index and its components (Im and If) were 0.483, 0.104, and 0.343, respectively.     

Diversity of mitochondrial DNA haplotypes in ethnic populations of the Volga-Ural region of Russia

The mtDNA polymorphism was analyzed in eight ethnic groups (N = 979) of the Volga-Ural region. Most mtDNA variants belonged to haplogroups H, U, T, J, W, I, R, and N1 characteristic of West Eurasian populations. The most frequent were haplogroups H (12-42%) and U (18-44%). East Eurasian mtDNA types (A, B, Y, F, M, N9) were also observed. Genetic diversity was higher in Turkic than in Finno-Ugric populations. The frequency of mtDNA types characteristic of Siberian and Central Asian populations substantially increased in the ethnic groups living closer to the Urals, a boundary between Europe and Asia. Geographic distances, rather than linguistic barriers, were assumed to play the major role in distribution of mtDNA types in the Volga-Ural region. Thus, as concerns the maternal lineage, the Finno-Ugric populations of the region proved to be more similar to their Turkic neighbors rather than to linguistically related Balto-Finnish ethnic groups.     

Tissue segregation of mitochondrial haplotypes in heteroplasmic Hawaiian bees: implications for DNA barcoding

The issue of mitochondrial heteroplasmy has been cited as a theoretical problem for DNA barcoding but is only beginning to be examined in natural systems. We sequenced multiple DNA extractions from 20 individuals of four Hawaiian Hylaeus bee species known to be heteroplasmic. All species showed strong differences at polymorphic sites between abdominal and muscle tissue in most individuals, and only two individuals had no obvious segregation. Two specimens produced completely clean sequences from abdominal DNA. The fact that these differences are clearly visible by direct sequencing indicates that substantial intra-individual mtDNA diversity may be overlooked when DNA is taken from small tissue fragments. At the same time, differences in haplotype distribution among individuals may result in incorrect recognition of cryptic species. Because DNA barcoding studies typically use only a small fragment of an organism, they are particularly vulnerable to sequencing bias where heteroplasmy and haplotype segregation are present. It is important to anticipate this possibility prior to undertaking large-scale barcoding projects to reduce the likelihood of haplotype segregation confounding the results.     

No association between mitochondrial DNA haplotypes and a female-limited mimicry phenotype in Papilio glaucus

Abstract Alternative alleles at a locus on the W chromosome of Papilio glaucus (causing dark or yellow wing colors, respectively) underlie a female-limited mimicry polymorphism thought to be maintained by balancing selection. In species with heterogametic females (i.e., the ZZ-male/ZW-female sex chromosome system), the mitochondrial DNA and the W chromosome are genetically linked because they are both maternally transmitted. We investigate the association of COI and COII mitochondrial DNA haplotypes with alternative W-linked phenotypes. Surprisingly, we find no congruence between mitochondrial DNA genealogies and inferred W-linked color alleles in P. glaucus. Using a maximum-likelihood phylogenetic approach, we reject the hypothesis of monophyly for darkmorph mitochondrial DNA lineages, even in the presence of putative low-frequency mimicry suppressor alleles or alternative melanizing factors. The most likely genealogical tree topologies assume more than one exchange event between mitochondrial DNA cytotype and the W-linked color morph. These results suggest that there is either paternal leakage of mitochondrial DNA or that more than two W-linked alleles underlie the alternative color morphs. Using data from an additional mitochondrial DNA locus, ND5, we show that pairwise linkage disequilibrium decays with physical distance between polymorphic sites. This finding suggests that genetic exchanges between maternal and paternal mitochondrial DNAs may have contributed to the lack of association we observe between phenotype and genotype.     

Numerous mitochondrial DNA haplotypes reveal multiple independent polyploidy origins of hexaploids in Carassius species complex

Evolutionary trajectory and occurrence history of polyploidy have been extensively studied in plants, but they remain quite elusive in vertebrates. Here, we sampled and gathered 4,159 specimens of polyploid Carassius species complex including 1,336 tetraploids and 2,823 hexaploids from a large geographic scale (49 localities) across East Asia, and identified a huge number of 427 diverse haplotypes of mitochondrial control region, in which 74 haplotypes with total occurrence frequency up to 75.498% were shared by hexaploids and tetraploids. Significantly, these diverse haplotypes were clustered into four major lineages, and many haplotypes of hexaploids and tetraploids were intermixed in every lineage. Moreover, the evolutionary trajectory and occurrence history of four different lineages were revealed by a simplified time‐calibrated phylogenetic tree, and their geographic distribution frequencies and haplotype diversity were also analyzed. Furthermore, lineage C and D were revealed to undergo population expansion throughout mainland China. Therefore, our current data indicate that hexaploids should undergo multiple independent polyploidy origins from sympatric tetraploids in the polyploid Carassius species complex across East Asia.     

Founder mitochondrial haplotypes in Amerindian populations.

It had been proposed that the colonization of the New World took place by three successive migrations from northeastern Asia. The first one gave rise to Amerindians (Paleo-Indians), the second and third ones to Nadene and Aleut-Eskimo, respectively. Variation in mtDNA has been used to infer the demographic structure of the Amerindian ancestors. The study of RFLP all along the mtDNA and the analysis of nucleotide substitutions in the D-loop region of the mitochondrial genome apparently indicate that most or all full-blooded Amerindians cluster in one of four different mitochondrial haplotypes that are considered to represent the founder maternal lineages of Paleo-Indians. We have studied the mtDNA diversity in 109 Amerindians belonging to 3 different tribes, and we have reanalyzed the published data on 482 individuals from 18 other tribes. Our study confirms the existence of four major Amerindian haplotypes. However, we also found evidence supporting the existence of several other potential founder haplotypes or haplotype subsets in addition to the four ancestral lineages reported. Confirmation of a relatively high number of founder haplotypes would indicate that early migration into America was not accompanied by a severe genetic bottleneck.     

Fitness and life-history traits of the two major mitochondrial DNA haplotypes of Drosophila subobscura

Mitochondrial DNA restriction site analyses on natural populations of Drosophila subobscura have proved the existence of two common, coexisting haplotypes (I and II), as well as a set of less frequent ones derived from them. To explain this distribution, experiments to date point practically to all possible genetic mechanisms being involved in the changes of gene frequencies (cytonuclear coadaptation, direct natural selection on mtDNA and genetic drift). In an attempt to find differences that help to understand the dynamics of these haplotypes and to detect the effect of selection, we measured certain fitness components and life-history traits (egg-larva and larva-adult viabilities and developmental times, longevity, resistance to desiccation and optimal density) of the two main haplotypes I and II when maintained in laboratory population cages. As a general trend, haplotype II showed a higher net fitness than haplotype I, which explains the superiority of haplotype II over haplotype I in experimental populations but not their coexistence in nature, where additional factors must be considered.     

Y-chromosome DNA haplotypes in Basques

One Y-specific DNA polymorphism (p49/TaqI) was studied in a sample of 97 French Basques and compared with those found in 7 other French, Iberian, and Italian populations. A particularly high frequency (72.2%) of Y-haplotype XV was observed in Basques, compared to values (mean of 41%) obtained in other Western Europeans. Basques were also characterized by virtual absence, or presence at a low level, of the South or Near Eastern haplotypes XII, VII, and VIII. Considered together, these results confirm that Basques are a very ancient European population which has had little previous contact with the Neolithics.     

Mitochondrial inheritance and the detection of non-parental mitochondrial DNA haplotypes in crosses of Agaricus bisporus homokaryons

This study evaluates mtDNA transmission in Agaricus bisporus, as well as the occurrence of non-parental haplotypes in heterokaryons produced by controlled crosses. Sixteen crosses were performed with blended liquid cultures, using different combinations of 13 homokaryotic strains. For each cross, different mtDNA haplotypes were present in each homokaryon. Heterokaryons generated from these crosses were subject to genetic analysis with RFLP markers to identify (i). karyotic status, (ii). mtDNA haplotype, and (iii). the occurrence of non-parental mtDNA haplotypes. These analyses generally supported the occurrence of uniparental mitochondrial (mt) inheritance in A. bisporus, with one mtDNA haplotype usually favoured in the new heterokaryon. The preponderance of one mtDNA haplotype in a new heterokaryon did not necessarily show a correlation with a greater mycelial growth rate for the parent homokaryon possessing that haplotype. Mixed mtDNA haplotypes and non-parental haplotypes were also identified in the heterokaryons from some crosses. Evidence for the occurrence of two mtDNA haplotypes in one heterokaryotic mycelium was observed in 8 of 16 crosses, suggesting the maintenance of true heteroplasmons after three successive subculturing steps. Non-parental mtDNA haplotypes were seen in heterokaryons produced from 7 of 16 crosses. The mating protocol described can be utilized to generate novel mtDNA haplotypes for strain improvement and the development of strain-specific markers. Mechanisms of mt selection and inheritance are discussed.     

Population dynamics of the 2 major mitochondrial DNA haplotypes in experimental populations of Drosophila subobscura.

The evolution of Drosophila subobscura mitochondrial DNA has been studied in experimental populations, founded with flies from a natural population from Calvià (Majorca, Balearic Islands, Spain). This population, like others founded in Europe, is characterized by the presence of 2 very common (>95%) mitochondrial haplotypes (named I and II) and rare and endemic haplotypes that appear at very low frequencies. Four experimental populations were established with flies having a heterogeneous nuclear genetic background, which was representative of the composition of the natural population. The populations were started with haplotypes I and II at an initial frequency of 50% each. After 33 generations, the 2 haplotypes coexisted. Random drift could be rejected as the only force responsible for the observed changes in haplotype frequencies. A slight but significant linear trend favouring a mtDNA (haploid) fitness effect has been detected, with a nonlinear deviation that could be due to a nuclear component. An analysis of chromosomal arrangements was made before the foundations of the cages and at generation 23. Our results indicated that the hypothesis that the maintenance of the frequencies of haplotypes I and II in natural populations could be due to their association with chromosomal arrangements remains controversial.     

CFTR haplotypes in northern Iranian population

Background

Cystic fibrosis (CF) is a multiorganic autosomal recessive disorder, caused by mutation in cystic fibrosis transmembrane conductance regulator (CFTR). CF is highly heterogeneous in Iranian population and molecular diagnosis based on direct identification of mutations is not completely efficient. The use of polymorphic intragenic markers not only can facilitate phenotype prediction in prenatal diagnosis by gene tracking, but also can lead to the demonstration of possible associations between haplotypes and specific mutations.

Methods

60 CF patients and 53 fertile normal subjects originating from North of Iran were analyzed for F508del mutation and c.1210-12T(5_9), c.1408A>G and c.744-33GATT(6_8) polymorphisms.

Results

c.1210-12T[7] is the most prevalent allele in normal individuals and CF non-F508del patients with 87.7%and 86.7% frequencies respectively. c.1408A>G survey showed that frequency of allele G and A is nearly equal in both non-F508del CF patients and normal individuals. c.744-33GATT(6_8) study showed that 7 repeat is the most prevalent allele in normal individuals and non-F508del CF patients with 80.2% and 82.1% frequencies respectively. The [c.1408A; c.1210-12T[9]; c.744-33GATT[6]] haplotype was only associated with mutant alleles including F508del.

Conclusions

The allelic distribution and heterozygosity results suggest that c.1408A>G, c.1210-12T(5_9) and c.744-33GATT(6_8) can contribute to carrier detection and prenatal diagnosis of CF in Iranian families with previous history of the disease.     

Pathogenic mitochondrial DNA mutations are common in the general population

Mitochondrial DNA (mtDNA) mutations are a major cause of genetic disease, but their prevalence in the general population is not known. We determined the frequency of ten mitochondrial point mutations in 3168 neonatal-cord-blood samples from sequential live births, analyzing matched maternal-blood samples to estimate the de novo mutation rate. mtDNA mutations were detected in 15 offspring (0.54%, 95% CI = 0.30–0.89%). Of these live births, 0.00107% (95% CI = 0.00087–0.0127) harbored a mutation not detected in the mother's blood, providing an estimate of the de novo mutation rate. The most common mutation was m.3243A→G. m.14484T→C was only found on sub-branches of mtDNA haplogroup J. In conclusion, at least one in 200 healthy humans harbors a pathogenic mtDNA mutation that potentially causes disease in the offspring of female carriers. The exclusive detection of m.14484T→C on haplogroup J implicates the background mtDNA haplotype in mutagenesis. These findings emphasize the importance of developing new approaches to prevent transmission.